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There are over 130 public cord blood banks in 35 countries. They are regulated by Governments and adhere to internationally agreed standards regarding safety, sample quality and ethical issues. In the UK, several NHS facilities within the National Blood Service harvest and store altruistically donated umbilical cord blood. Trained staff, working separately from those providing care to the mother and newborn child, collect the cord blood. The mother may consent to donate the blood for research and/or clinical use and the cord blood bank will make the blood available for use as appropriate.
The biggest advantage for cord blood is the “immaturity” of the cells, which means transplants do not require an exact match. For bone marrow and peripheral blood transplants, donors need to match the patient’s cellular structure. However, cord blood cells can adapt to a wide variety of patients, and don’t require donor matching. Chances for graft-versus-host disease are also much lower for cord blood transplants.
As cord blood is inter-related to cord blood banking, it is often a catch-all term used for the various cells that are stored. It may be surprising for some parents to learn that stored cord blood contains little of what people think of as “blood,” as the red blood cells (RBCs) can actually be detrimental to a cord blood treatment. (As we’ll discuss later, one of the chief goals of cord blood processing is to greatly reduce the volume of red blood cells in any cord blood collection.)
Most of the diseases on the proven treatment list are inherited genetic diseases. Typically, these treatments require a donor transplant, as from a sibling. In fact, research shows that treatments using cord blood from a family member are about twice as successful as treatments using cord blood from a non-relative.9a, 17 To date, over 400 ViaCord families have used their cord blood 56% were for transplant.1
Parents sign a consent form, giving the public bank permission to add their child’s cord blood to a database. This database will match transplant patients with a suitable donor. No information about the donor, or their family, is displayed online. The website used in America is Be The Match. They maintain a database of donations and banks across the country, while also working with foreign banks. Your child’s cord blood could save someone living anywhere in the world.
Your baby’s cord blood tissue, or umbilical cord lining, holds different stem cells. Researchers are breaking new ground with these cells, with applications which could prove to be beneficial in the future for the treatment of many more common diseases.
Cord blood is used to treat children with cancerous blood disorders such as leukaemia, or genetic blood diseases like Fanconi anaemia. The cord blood is transplanted into the patient, where the HSCs can make new, healthy blood cells to replace those damaged by the patient’s disease or by a medical treatment such as chemotherapy for cancer.
The Leading the Way LifeSaving Ambassadors Club is a recognition program honoring sponsor groups for outstanding performance in reaching or exceeding blood drive collections goals. CBC presents a Leading the Way plaque to winning sponsors on an annual basis. The award is based on three levels of achievement:
Stem cells from cord blood can be given to more people than those from bone marrow. More matches are possible when a cord blood transplant is used than when a bone marrow transplant is used. In addition, the stem cells in cord blood are less likely to cause rejection than those in bone marrow.
A stem cell has the potential to become one of many different types of cells. Stem cells are unique cells: They have the ability to become many different types of cells, and they can replicate rapidly. Stem cells play a huge part in the body’s healing process, and the introduction of new stem cells has always showed great promise in the treatment of many conditions. It wasn’t until we found out where and how to isolate these cells that we started using them for transplants. Although a person’s own stem cells are always 100 percent compatible, there are risks in using someone else’s stem cells, especially if the donor and recipient are not immediately related. The discovery of certain markers allows us to see how compatible a donor’s and host’s cells will be. The relatively recent discovery of stem cells in the umbilical cord’s blood has proven advantageous over acquiring stem cells from other sources. Researchers are currently conducting clinical trials with stem cells, adding to the growing list of 80 diseases which they can treat.
After your baby is born, the umbilical cord and placenta are usually thrown away. Because you are choosing to donate, the blood left in the umbilical cord and placenta will be collected and tested. Cord blood that meets standards for transplant will be stored at the public cord blood bank until needed by a patient. (It is not saved for your family.)
Please note: ClinImmune Labs – University of Colorado Cord Blood Bank – CariCord’s activities for New York State residents are limited to collection, processing, and long-term storage of umbilical cord tissue. Possession of a New York State license for such collection, processing, and long-term storage does not indicate approval or endorsement of possible future uses or future suitability of umbilical cord tissue-derived cells.
Through these two means, we are always producing more cells. In fact, much of your body is in a state of constant renewal because many cells can live for only certain periods of time. The lifespan for a cell in the stomach lining is about two days. Red blood cells, about four months. Nerve and brain cells are supposed to live forever. This is why these cells rarely regenerate and take a long time if they do.
‡ Payment Plan Disclosures for in-house CBR 6-Month Plan (interest free) – No credit check required. The 6-month plan requires a $10/month administrative fee. The plans may be prepaid in full at any time.
Because of the invasive procedure required to obtain the bone marrow, scientist continued to look for a better source, which eventually lead to the discovery of similar stem cells in cord blood in 1978. Cord blood was used in its first transplant in 1988, and cord blood has since been shown to be more advantageous than other means of acquiring similar stem cells and immune system cells. This is because umbilical cord blood can be considered naïve and immature compared to other sources. Cord blood has not been exposed to disease or environmental pollutants, and it is more accepting of foreign cells. In this case, inexperience makes it stronger.
As most parents would like to bank their babies’ cord blood to help safeguard their families, it is often the cost of cord blood banking that is the one reason why they do not. Most cord blood banks have an upfront fee for collecting, processing and cryo-preserving the cord blood that runs between $1,000 and $2,000. This upfront fee often also includes the price of the kit provided to collect and safely transport the cord blood, the medical courier service used to expedite the kit’s safe shipment, the testing of the mother’s blood for any infectious diseases, the testing of the baby’s blood for any contamination, and the cost of the first full year of storage. There is then often a yearly fee on the baby’s birthday for continued storage that runs around $100 to $200 a year.
Once you arrive at the hospital, all you need to worry about is having a safe birth. There are a few minor things that you and your family must remember at the hospital, but your priority should be birth and spending time with your newborn.
A cord blood bank may be private (i.e. the blood is stored for and the costs paid by donor families) or public (i.e. stored and made available for use by unrelated donors). While public cord blood banking is widely supported, private cord banking is controversial in both the medical and parenting community. Although umbilical cord blood is well-recognized to be useful for treating hematopoietic and genetic disorders, some controversy surrounds the collection and storage of umbilical cord blood by private banks for the baby’s use. Only a small percentage of babies (estimated at between 1 in 1,000 to 1 in 200,000[8]) ever use the umbilical cord blood that is stored. The American Academy of Pediatrics 2007 Policy Statement on Cord Blood Banking stated: “Physicians should be aware of the unsubstantiated claims of private cord blood banks made to future parents that promise to insure infants or family members against serious illnesses in the future by use of the stem cells contained in cord blood.” and “private storage of cord blood as ‘biological insurance’ is unwise” unless there is a family member with a current or potential need to undergo a stem cell transplantation.[8][9] The American Academy of Pediatrics also notes that the odds of using a person’s own cord blood is 1 in 200,000 while the Institute of Medicine says that only 14 such procedures have ever been performed.[10]
^ a b c American Academy of Pediatrics Section on Hematology/Oncology; American Academy of Pediatrics Section on Allergy/Immunology; Lubin, BH; Shearer, WT (January 2007). “Cord blood banking for potential future transplantation”. Pediatrics. 119 (1): 165–70. doi:10.1542/peds.2006-2901. PMID 17200285.
The first successful cord blood transplant (CBT) was done in 1988 in a child with Fanconi anemia.[1] Early efforts to use CBT in adults led to mortality rates of about 50%, due somewhat to the procedure being done in very sick people, but perhaps also due to slow development of immune cells from the transplant.[1] By 2013, 30,000 CBT procedures had been performed and banks held about 600,000 units of cord blood.[2]
Finally, the healthy stem cells are placed into long-term cryogenic storage. Compared to other stem cell sources, cord blood units are available very quickly since a doctor can remove them from storage and send them to the transplant hospital within a few days.
The immune system has a way to identify foreign cells; it’s what allows the body to defend itself. So although transplants were proving successful after the first in 1956, they were limited to twins because their shared genetic makeup made them 100 percent compatible. This took a turn in 1958, when scientists discovered a protein present on the surface of almost all cells that lets the body know if the cell is one of its own cells or a foreign cell. In 1973, we finally learned enough about these compatibility markers (called human leukocyte antigens or HLAs) to perform the first unrelated bone marrow transplant.
​nbiased and factual information. The Foundation educates parents, health professionals and the general public about the need to preserve this valuable medical resource while providing information on both public cord blood donation programs and private family cord blood banks worldwide. Learn more about our global community.
^ a b Walther, Mary Margaret (2009). “Chapter 39. Cord Blood Hematopoietic Cell Transplantation”. In Appelbaum, Frederick R.; Forman, Stephen J.; Negrin, Robert S.; Blume, Karl G. Thomas’ hematopoietic cell transplantation stem cell transplantation (4th ed.). Oxford: Wiley-Blackwell. ISBN 9781444303537.
Each cord blood bank has different directions for returning the consent form. Some banks may ask you to mail the consent form along with the health history forms or to bring the original consent form with you to the hospital. Other banks may have you finish the form at the hospital. Follow the directions from your public cord blood bank.
The cord blood of your baby is an abundant source of stem cells that are genetically related to your baby and your family. Stem cells are dominant cells in the way they contribute to the development of all tissues, organs, and systems in the body.
Several research teams have reported studies in animals suggesting that cord blood can repair tissues other than blood, in diseases ranging from heart attacks to strokes. These findings are controversial: scientists often cannot reproduce such results and it is not clear HOW cord blood may be having such effects. When beneficial effects are observed they may be very slight and not significant enough to be useful for developing treatments. If there are positive effects, they might be explained not by cord blood cells making nerve or heart cells, but by the cells in the cord blood releasing substances that help the body repair damage.
If you do decide to bank your baby’s cord blood, there’s one more thing to keep in mind: It’s best not to make it a last-minute decision. You should coordinate with the bank before your baby is born so nothing is left to chance.

Cord blood has an abundance of stem cells and immune system cells, and the medical uses of these cells has been expanding at a rapid pace. As these cells help the body re-generate tissues and systems, cord blood is often referred to as a regenerative medicine.
Hematopoietic stem cells can be used to treat more than 70 types of diseases, including diseases of the immune system, genetic disorders, neurologic disorders, and some forms of cancer, including leukemia and lymphoma. For some of these diseases, stem cells are the primary treatment. For others, treatment with stem cells may be used when other treatments have not worked or in experimental research programs.
Unlike other banks, CBR uses a seamless cryobag for storage. The seamless construction decreases the potential for breakage that can occur in traditional, seamed-plastic storage bags. Prior to storage, each cryobag is placed in a second overwrap layer of plastic, which is hermetically sealed as an extra precaution against possible cross contamination by current and yet unidentified pathogens that may be discovered in the future. CBR stores the stem cells in vaults, called dewars, specially designed for long-term cryostorage. The cord blood units are suspended above a pool of liquid nitrogen that creates a vapor-phase environment kept at minus 196 degrees Celsius. This keeps the units as cold as liquid nitrogen without immersing them in liquid, which can enable cross-contamination. Cryopreserved cord blood stem cells have proven viable after more than 20 years of storage, and research suggests they should remain viable indefinitely.
In March 2004, the European Union Group on Ethics (EGE) has issued Opinion No.19[16] titled Ethical Aspects of Umbilical Cord Blood Banking. The EGE concluded that “[t]he legitimacy of commercial cord blood banks for autologous use should be questioned as they sell a service, which has presently, no real use regarding therapeutic options. Thus they promise more than they can deliver. The activities of such banks raise serious ethical criticisms.”[16]
#MothersDay is just around the corner and we are celebrating by sharing one of our employee’s journey as a #newmom. Tiffany shares 5 things she’s learned being a new parent to a 6 month old. Can you relate? blog.cordblood.com/2018/05/five-t…
Checked to make sure it has enough blood-forming cells for a transplant. (If there are too few cells, the cord blood unit may be used for research to improve the transplant process for future patients or to investigate new therapies using cord blood, or discarded.)
Be the Match is a nonprofit organization that supports public cord blood banks’ efforts to encourage donations. It maintains the largest public listing of donated cord blood available for transplantation in the United States. The organization has facilitated more than 7,000 unrelated cord blood transplants since the year 2000.
MSCs can turn into bone, cartilage, fat tissue, and more. Although they are associated with bone marrow, these cells are also found in umbilical cord blood. These cells can function as connective tissue, which connects vital organs inside the body. Like HSCs, MSCs are multipotent.
Experts believe that umbilical cord blood is an important source of blood stem cells and expect that its full potential for treatment of blood disorders is yet to be revealed. Other types of stem cell such as induced pluripotent stem cells may prove to be better suited to treating non-blood-related diseases, but this question can only be answered by further research.
Donating your baby’s cord blood to a public bank is always free. The limitations of the public banking network in the United States are: they only collect donations at large birthing hospitals in ethnically diverse communities, the mother must pass a health screening, they prefer registration by 34 weeks of pregnancy, and they only save the largest cord blood collections. The potential reward of public donation is that your baby could Be The Match to save a life!
Since most banks require mothers to sign up for donation between the 28th and 34th week of pregnancy, families must decide to donate ahead of time. If you are considering a public bank for your child’s cord blood, contact the bank and make sure you still have time.
Your child’s cord blood will also be tested for contamination. Staff at the lab will test the unit, along with a blood sample from the mother, and check for any possible problems. Contamination may happen in the hospital room or during travel to the lab. If the cells are contaminated, they may still be used in a clinical trial.
Along with cord blood, Wharton’s jelly and the cord lining have been explored as sources for mesenchymal stem cells (MSC),[19] and as of 2015 had been studied in vitro, in animal models, and in early stage clinical trials for cardiovascular diseases,[20] as well as neurological deficits, liver diseases, immune system diseases, diabetes, lung injury, kidney injury, and leukemia.[21]
Cord blood is the blood that remains in the umbilical cord and placenta following birth. This blood is usually discarded. However, cord blood banking utilizes facilities to store and preserve a baby’s cord blood. If you are considering storing your baby’s cord blood, make sure to use a cord blood bank accredited by the American Association of Blood Banks (AABB), like Viacord.